Fluid pressure brake



July 20, Q FARMER FLUID PRES SURE BRAKE Filed May 6, 1936 3 Sheets-Sheet l INVENTOR OLYDEOFARMER ATTORN EY July 20, 1937.

c. c. FARMER FLUID PRESSURE BRAKE 3 Sheets-Sheet 2 Filed May 6, 1956 mV QR h@ \R MK.

INVENTOR CLYDE c. FARMEP BY a g RNEY ATTO

July 20, 1 93 7.

INVENTOR CLYDE C. FARMER ATTORN EY Patented July 20, 1937 l'l'E STA.

2,087,625 FLUID PRESSURE BRAKE Application May 6, 1936, Serial No. 78,980

19 Claims.

This invention relates to fluid. pressure brakes and more particularly to the type adapted tooperate upon a reduction in brake pipe pressure to effect an application of the brakes and upon an increase in brake pipe pressure to effect a release of the brakes.

In Patent No. 2,031,213 issued to Clyde 0. Farmer on February 18, 1936 there is disclosed a brake controlling valve device which includes a service portion adapted to operate upon a service reduction in brake pipe pressure to effect a. service application of the brakes, and an emergency portion adapted to operate along with the service portion upon an emergency reduction in brake pipe pressure to eiiect an emergency application of the brakes.

The emergency portion comp-rises a piston subject to the opposing pressures of the brake pipe and a chamber and adapted to operate upon a service reduction in brake pipe pressure to move an auxiliary slide valve relative to a main slide valve to a service position in which fluid under pressure is vented from the quick action chamber at the same rate as the brake pipe pressure is reduced so as to thereby prevent further movement of said piston and auxiliary slide valve upon a service reduction in brake pipe pressure.

The communication through which fluid under pressure is vented from the quick action chamber in service position of the auxiliary slide valve is so restricted however as to' prevent the pressure in the quick action chamber reducing as fast as the brake pipe pressure reduces upon an emergency reduction, so that upon an emergency reduction in brake pipe pressure, a sufiicient differential of pressures isobtained on the emergency piston to move said piston and the auxiliary slide valve past service position to an emergency position in which fluid under pressure is vented from the quick action chamber'to a brake pipe vent valve device. The brake pipe'vent valve device is thereby operated to efiect a sudden venting of fluid under pressure from the brake pipe for propagating emergency action through a train and thereby eiiecting an emergency application of the brakes on the train.

The emergency piston and auxiliary slide valve are adapted to be moved to service position when, upon a reduction in brake pipe pressure, a small diiierential, such as .4 of a pound, is obtained on said piston. In this position a stabilizing spring comes into action which opposes movement of the piston and auxiliary slide valve to emergency position. The spring has a force equivalent to a small differential of fluid pressures, such. as .5 of

a pound, on the emergency piston, and therefore, acts in conjunction with the venting of fluid under pressure from the quick action chamber in service position to prevent movement of the emergency piston and auxiliary slide valve past service position to emergency position upon a service reduction in brake pipe pressure. It will be noted that in order for the piston to move the auxiliary slide valve to emergency position, the differential of fluid pressures on the piston must be such as to overcome this spring, or equal to at least .9 of a pound.

It is possible that after an emergency valve device has been in use for some time, the resistance to movement of the parts, and particularly the piston, may become greater than normal, due for instance to accumulations of foreign matter, lack of lubrication, the use of an improper lubricant, orfor other reasons, and consequently a differential of fluid pressures greater than the .4 of a pound above mentioned may be required to start the piston and auxiliary slide valve moving upon a reduction in brake pipe pressure. So long however as the resistance to movement of the emergency piston and auxiliary slide valve does not increase beyond a certain degree, the action of the stabilizing spring on the piston in conjunction with the venting of fluid under pressure from the quick action chamber will prevent a sufficient differential of fluid pressures being developed on the piston to move same and the auxiliary slide valve past service'position.

' It is possible however that the static resistance to movement of the emergency piston and auxiliary slide valve and particularly the piston, may become such as to require a diiierential of fluid pressures on the piston exceeding the .903? a pound above mentioned to start said piston and the auxiliary slide valve moving. Then if the kinetic resistance to movement of these parts should happen to be sufficiently low, there is a possibility that the piston may move the auxiliary slide valve through service position so fast that insufficient reduction in pressure in the quickaction chamber will be effected to reduce the differential on the piston to a degree which willnot overcome the stabilizing spring. In such a case, the piston is liable to move the auxiliary slide valve to emergency position upon a' service'redum tion in brake pipe pressure and thereby initiate an emergency application of the'brakes on a train.

It is undesirable to have an emergency application of the brakes occur upon a service reduction in brake pipe pressure and the principal object of the invention is to provide an improved emergency valve device having means for ensuring that an emergency application of the brakes will not occur upon a service reduction in brake pipe pressure.

This object is attained by providing in the emergency piston a flexible diaphragm which is responsive to a service reduction in brak-e pipe pressure to move an .auxiliary slide valve on the main slide valve to a position for venting fluid under pressure from the quick action chamber at a service rate. The operation of a flexible diaphragm is not materially influenced by foreign matter or lubrication, as is a piston having sliding contact with a cylinder wall, so that the diaphragm can therefore be depended upon to operate an auxiliary slide valve as desired upon a service reduction in brake pipe pressure. An advantage of this improved construction is that it may be incorporated in the emergency valve device disclosed in the aforementioned patent by the mere substitution and/or addition of new parts, as will be hereinafter more fully described.

Other objects and advantages will be apparent from the following more detailed description of the invention. p

In the accompanying drawings; Fig. 1 is a diagrammatic view, mainly in section, of a portion of a fluid pressure brake equipment embodying one form of the invention; Fig. 2 is a view similar to Fig. 1 of a brake controlling valve device embodying a modified form of the invention; and Fig. 3 is a view similar to Fig. 1 embodying still another form of the invention.

The portion of the fluid pressure brake equipment shown in Figs. 1, 2, and 3, of the drawings is in general similar to the emergency portion of the brake equipment disclosed in the aforementioned patent, only those parts being shown however which are deemed necessary to a clear understanding of the invention.

The portion of the fluid pressure brake equipment shown in Fig. l of the drawings comprises a pipe bracket I upon one face of which is mounted a filler piece 2 which carries an emergency valve device 3. The pipe bracket I has another face (not shown) upon which is adapted to be mounted a service valve device (not shown), and the bracket I is adapted to be connected by a pipe 4 to an auxiliary reservoir (not shown), by a pipe 5 to the usual pressure retaining valve device (not shown), by a pipe 6 to an emergency reservoir I, by a pipe 8 to a brake cylinder 9 and by a pipe Ill to a brake pipe II, in the same manner as disclosed in the aforementioned patent.

The emergency valve device comprises a casing having a bore containing an emergency piston I2 which has at one side a chamber I3 open to a concentric bore I4 formed in the filler piece 2 and communicating with the brake pipe II through a chamber I5, passages 69 and 39 and pipe Ill.

The emergency piston I2 has at the opposite side a valve chamber I6 connected through a passage I! to a quick action chamber I8. A main slide valve I9 and an auxiliary slide valve mounted to slide on the main slide valve are disposed in chamber I6. A 'stem 2| projects from the piston I2 into chamber I6 and is provided with a cavity in which the auxiliary slide valve 20 is disposed so as to be moved with the piston I2. The main slide valve I9 is loosely disposed between a shoulder 22 formed on the back of piston I2 and a shoulder 23 formed on the end of the stem 2I.

The piston I2 is provided with a packing ring 24 adapted to work in the bore in the emergency valve casing and has a hollow cup shaped extension 25 which'projects into the bore I5.

A ring shaped cap 28 is secured in the outer end of the piston extension 25 preferablyby screwthreaded engagement and is provided on its outer face with an annular bead Zl adapted to engage and seal against a gasket 28 secured to the end wall of bore M by means of a flanged nut E25 having screw-threaded engagement with the filler piece 2. I

A flexible diaphragm 29 is disposed within the piston extension 25'and has a cylindrical portion 30 which is adapted to bear against an inner cylindrical surface of said extension. The diaphragm 23 has an inner, centrally perforated, fiat ring portion 3i which is joined to one end of the cylindrical portion by means of an annular convolution which is substantially semicircular in cross-section. The other end of the cylindrical portion 33 of the diaphragm 29 is joined to an inwardly directed annular flange 32 which is clamped to the cap 26 between the inner surface thereof and a surface on a follower ring 33 which is secured to the cap 25 by a plurality of cap screws 34. It is desired to point out that by directing the clamping flange 32 of the diaphragm 29 inwardly, the maximum area of diaphragm is obtained within a space the diameter of which is substantially no greater than that of the piston l2, and this is very desirable in that it provides a diaphragm of sufficient size to be sensitive to slight fluctuations in fluid pressure for a purpose which will be hereinafter described.

The flat ring portion SI of the diaphragm 29 is clamped between a follower 35 and a follower 36 by means of a stud 31 which is secured to the follower 35 by screw-threaded engagement and extends through a central aperture in the follower 36 and is provided with a shoulder 38 engaging the follower 36.

The follower 35 is slidably mounted in a suitable bore All in the piston I2 and is provided with a stem M which extends through a suitable cavity formed in the piston stem 2!. A guide 42 is provided on the end of the stem 4| and is slidably mounted in a bore 4 3 in the piston stem 2|. An auxiliary slide valve M is mounted to slide on the main slide valve I9 and is disposed between spaced shoulders on the stem 4! so as to be movable with said stem.

A spring stop in the form of a plate 45 is secured to the outer face of the cap 26 by the screws 34 and interposed between said plate and the diaphragm follower 36 is a service spring 46. This plate is provided with a central aperture through which the head 41 of the stud 31 is adapted to freely move. A spring stop 48 is slidably mounted on the stud 3'! beneath the head 41 and an emergency spring 49 is interposed between the spring stop 48 and the follower 36 and acts to urge said spring stop into engagement with the head 41 of the stud 31. The outside diameter of the spring stop 48 is greater than the diameter of the aperture in plate 45 through which the stud head 41 operates so that said spring stop will engage saidplate after a certain amount of movement of the diaphragm 29 to.- wards the right hand.

A stabilizing spring 50 is interposed between spring stop 45 and the bottom wall of chamber I5 in the filler piece 2 and acts at all times to urge the piston I2 in a direction towards the left and.

It will be noted from the above description that the right hand face of the flexible diaphragm- 29 is subject to brake pipe pressure through the aperture in the spring stop t5, While the left hand face of said diaphragm is subject to quick action chamber pressure in valve chamber It through a port 59 in the piston ii.

A stem having a head 52 on one end engaging one face of a flexible diaphragm 53 extends through a suitable opening M in the piston stem 21 and engages the main slide valve 59 within a recess 55. A spring 56 and the pressure of fluid in a chamber 51* at the opposite side of the diaphragm E3 is adapted to apply pressure to the head 52 of the stem and thereby to the main slide valve to urge same against its seat. The chamber 57 is in constant communication with the emergency reservoir l through passages 58 and 59 and pipe 6.

The left hand end of, the emergency valve chamber i6 is closed by a cap which is provided with a bore larger in diameter but concentric to the bore of said chamber thereby forming on the emergency valve casing an annular shoulder iii. A plunger. 62 is slidably mounted in the bore in cap (it and is urged into engagement with the shoulder 6i by means of a spring 63.

With the parts of the apparatus in their normal position as shown in Fig. 1 of the drawings, the piston stem 2i and a rearwardly extending finger b t on the slide valve 23 engage the plunger 62 which thereby acts to define said normal position. In this connection it is desired to point out that the pressure of spring 63 exceeds that of the stabilizing spring 53 so that the plunger 62 can be maintained against the shoulder 6i by spring 63 for the purpose just described.

Associated with the emergency valve device is a brake pipe vent valve device which comprises a vent valve 65 contained in a chamber 66 in constant communication with the brake pipe H through passages 67!, 63, S9, and 39 and pipe iii. A spring 78 is disposed in chamber 66 and acts to urge the vent valve 65 into engagement with a seat rib ii for closing communication from chamber 66 to a chamber l2 which is open to the atmosphere through an atmospheric passage 73.

A piston it is provided for unseating the vent valve 65 and is operatively connected thereto through the medium of a stem 75. This piston has at one side a chamber it connected to a pas sage ll leading to the seat of the main slide valve i9 and has at the opposite side a chamber l8 open to the atmosphere through the passage ?3. a

A restricted blow down timing port it is pro vided through the piston E i connecting chambers it to '28, while a by-pass leakage groove 80 is provided in the casing connecting the chambers at the opposite sides of said piston when said piston is in its normal position.

In operation, the service application portion (not shown) of the brake equipment operates in initially charging the brake equipment, in effecting servi e and emergency applications of the brakes and in releasing the brakes after an application in the same manner as described in the aforementioned patent, and in View of. the fact that such operation is not pertinent to the invention the following description of operation will be limited to the operation of the emergency valve device which embodies the invention.

With the parts of the emergency valve device 3 in their normal position, as shown in the drawings, fluid under pressure flows from chamber 13 through a restricted charging port 8! to passage H and from thence in a direction toward the right hand to the quick action chamber l8 and in the opposite direction to the emergency valve chamber It thus charging said chambers with fluid at the pressure carried in the brake pipe ll.

With the main slide valve E9 in its normal position passage i1 is lapped and consequently the vent valve piston chamber i6 is at atmospheric pressure due to being vented through port l9 and groove 8!). Spring it! therefore acts to hold the vent valve 75 seated against the seat rib H, and chamber 63 becomes charged with fluid under pressure supplied from the brake pipe H to passage 69 by way of said passage and passages 68 and 6?.

When a service rate of reduction in brake pipe pressure is effected the pressure of fluid in chamber l5, bore M and chamber is at the right hand face of the emergency piston i3 and flexible diaphragm 29 reduces accordingly, and fluid under pressure then tends to flow back from the valve chamber its and quick action chamber it! through the charging port M. This port is however so restricted that a differential of pressures is developed on the piston l2 and diaphragm 29 and when this differential on said diaphragm becomes sufficient it overcomes the opposing pressure of the service spring 56 and deflects said diaphragm towards the right hand.

This movement of the diaphragm 29 pulls the auxiliary slide valve i itowards the right hand until a port 82 therein registers with a port 83 in the main slide valve l9. Through the communication thus established fluid under pressure is permitted to flow from the valve chamber it and quick action chamber E8 to a cavity i in the seating face of the main slide valve and from thence to the atmosphere through an atmospheric passage 85, thereby reducing the pressure in said chambers at the same rate as the brake pipe pressure reduces upon a service rate of reduction. This prevents the differential of pressures acting on the diaphragm 2%) from increasing sufliciently to keep said diaphragm moving so as to move the auxiliary slide valve past the position just described upon a service reduction in brake pipe pressure.

At about the time the port 82 in the auxiliary slide valve M registers with the port 83 in the main slide valve, the spring stop it engages the spring stop t5, so that further deflection. of the diaphragm 2% towards the right hand is opposed by the spring as in addition to the spring 55. The engagement between the spring stops ts and 55 thus defines the service position of the flexible diaphragm 29 and auxiliary slide valve ti t and acts in conjunction with the reducing of pressure in valve chamber it throughthe service ports 82 In initially charging the brake equipment fluid under pressure is supplied to the brake pipe ll inv and 83 to prevent suilicient differential of fluid pressures being developed on the diaphragm to cause said diaphragm and the auxiliary'slide valve I4 to move past the service position upon a service reduction in brake pipe pressure.

The purpose of spring 46 is to define the differential of fluid pressures required on the diaphragm 29 to move the auxiliary slide valve 44 to service position and thereby prevents such movement upon a less difierential which may be encountered in service due to slight fluctuations in brake pipe pressure which may be caused by operation of the usual feed valve device (not shown).

e spring 58 acts with such force on the piston i2 as to ensure that said piston will not be moved from its normal position by the differential of pressures required to deflect the diaphragm 29 and move the auxiliary slide valve 44 to their service position, as might occur if for any reason the resistance to movement of the piston 12 and auxiliary slide valve 26 should become lower than that of the diaphragm 29 and slide valve 44.

When upon a service reduction in brake'pipe pressure, the pressure in valve chamber 56 and quick action chamber l8 has been reduced as above described to substantially equal the brake pipe pressure in bore M, the spring 45 deflects the diaphragm towards the left hand and causes the slide valve i t to lap port 83 so as to cut off further venting of fluid under pressure from the valve chamber 15 and quick action chamber I8.

Further service reductions in brake pipe pressure cause the above operation of diaphragm 29 and the auxiliary slide valve 44 to be repeated, so that the emergency piston 52 is prevented from moving from its normal position so long as the reductions in brake pipe pressure are at a service rate.

When a sudden reduction in brake pipe pressure is effected at an emergency rate, the diaphragm 29 operates as above described to move the slide Valve M to service position in which fluid under pressure tends to be vented from the Valve chamber l6 and quick action chamber through the service ports Hand 83, but this communication is so restricted with respect to an emergency rate of reduction in brake pipe pressure, that the differential of pressures on the diaphragm promptly increases sufliciently to overcome the pressure of the emergency spring 49.

The diaphragm then moves further to the right into engagement with the follower ring 33'and in so doing moves the auxiliary slide valve past service position to an overtravel position in which the service port 33 is lapped by the slide valve 54.

At about the time the slide valve 44 laps the service port 83, suflicient differential of fluid pressures is obtained on the emergency piston l2 to overcome the static resistance to movement of said piston and the auxiliary slide valve 29 and the resistance of the stabilizing spring 58, whereupon said piston moves said valve towards the right hand until the shoulder 23 engages the end of the main slide valve is. In this position of the auxiliary slide valve 28, an emergency port 86 is opened to valve chamber I6 which. permits fluid under pressure to flow from said chamber and the quick action chamber A8 to passage 11 and from thence to the vent valve piston chamber 16.

The rate at which fluid under pressure is thus 7 supplied to the vent valve piston chamber 16 exceeds the venting capacity of port '19 and groove 80, so that suificient pressure is promptly obtained on the vent valve piston 14 to actuate same to unseat the vent valve 65.

When the vent valve is unseated, fluid under pressure is suddenly vented from the brake pipe II by Way of pipe I8, passages 39, 69, 68, 61, past the vent valve 65 and from thence to the atmosphere through passage 13. This sudden venting of fluid under pressure from the brake pipe is adapted to propagate emergency action through out a train in the well known manner and also increases the differential of fluid pressures on the emergency piston I2 to a degree sufficient to move the main slide valve H) to a position defined by the engagement of the sealing bead 21 wit the gasket 28.

In this position of the main slide valve IS, a cavity 81 therein connects the emergency reservoir passage 59 to a passage 88 leading to the brake cylinder 9 which permits fluid under pressure to equalize from said reservoir into said brake cylinder to provide high emergency brake cylinder pressure. In this position of the main slide valve, the passage Ti is uncovered by the left hand end thereof so that fluid under pressure from the valve chamber l6 and quick action chamber l8 continues to be supplied to the vent valve piston chamber 16.

The pressure of fluid thus supplied to the vent valve piston chamber 16 gradually reduces through the vent port 19 which is of such size with respect to the combined volumes of valve chamber l6 and quick action chamber l8 as to cause the vent valve piston M to hold the vent valve 65 in the venting position sufiiciently long to ensure substantially complete venting of fluid under pressure from the brake pipe, following which the spring 18 acts to seat the vent valve 65 and return the piston M to its normal position sothat the brake equipment may be recharged and the brakes released, whenever it is desired to do so a When the quick action chamber pressure in valve chamber [6 is reduced sufficiently in the manner above described, the springs 46 and 49 return the diaphragm 29 and auxiliary slide valve 44 to their normal position with respect to the piston l2, and the spring 58 moves said piston and the auxiliary slide valve 20 towards the left hand until the shoulder 22 on the back of the piston engages the end of the main slide valve 19. The piston l2 ceases movement in this position since the force of spring 58 is insufficient to move the slide valve I79 which is pressed against its seat by emergency reservoir pressure plus the pressure of spring 55 in chamber acting downwardly on the diaphragm 53.

When it is desired to efiect a release of the brakes after an emergency application, fluid under pressure is supplied to the brake pipe H and from thence flows to the emergency piston chamber I3 at the right hand side of the emergency piston l2. When the pressure is thus increased sufliciently on said piston to overcome resistance to movement of the main slide valve l9, said piston shifts said slide valve back to its normal position as shown in the drawings.

In the normal position of the emergency piston, the restricted feed port 8| is opened to chamber B so that fluid under pressure then flows from chamber l3 to the emergency valve cham ber l8 and quick action chamber IS.

The size of the feed port BI is such with respect to the rapid rate of increase in brake pipe pressure obtained at the start of charging of the brake pipe after an emergency application that the brake pipe pressure in chamber it increases more rapidly than the quick action chamber pressure and when thus increased sufiiciently overcomes the opposing pressure of spring 83 acting on the movable stop 62 and moves the piston l2 and main slide valve l9 to a backdump position as defined by engagement of the left hand face of the piston with the emergency valve casing.

In back dump position of the main slide valve l9, cavity 8'! therein connects the brake cylinder passage 88 to a passage 89 which permits fluid under pressure to flow from the brake cylinder d to passage 39 and from thence past two serially arranged check valves 95] and 9! to passage 6i and from thence to the brake pipe ii. The con-- sequent. equalization of fluid under pressure from the brake cylinder into the brake pipe provides a sudden local increase in brake pipe pressure which is adapted to cause the emergency valve device on the next car in a train to operate in like manner and thereby propagate this action serially from car to car throughout a train so as to hasten the increase in brake pipe pressure.

After this back-dump operation, fluid under pressure supplied to the brake pipe in the usual well known manner continues to increase the brake pipe pressure to the degree normally carried and at the same time fluid under pressure continues to flow from the emergency piston chamber 13 through the feed port 8i to the emergency valve chamber 58 and quick action chamber i8. When the pressure of fluid in these chambers is increased to substantially that in the brake pipe, the action of spring 53 on the stop 52 returns the emergency piston i2 and main slide valve iii to their normal position as shown in the drawings.

If while recharging the brake equipment the emergency valve chamber i5 and quick action chamber it become charged to a pressure slightly in excess of that in the emergency reservoir 1, the pressure in chambers will unseat the serially arranged check valves 92 and 93. Fluid under pressure will then flow from said chambers to passage 58 and from thence to the emergency reservoir 7 which is of large volume and thus able to prevent said chambers from becoming charged to a pressure in excess of that normally carried in the brake pipe.

From the above description it will now be noted that the service venting of fluid under pressure from the valve chamber it and quick action chamber i3 is controlled by the service auxiliary slide valve 44 and flexible diaphragm 29 and since the size of said valve is relatively small as compared to the area of said diaphragm, and the operation of the diaphragm is not materially affected by foreign matter or lubrication, it will be evident that the diaphragm will operate the valve 44 in the manner desired and at substantially the differential of pressures desired, as governed by spring 48 upon a service reduction in brake pipe pressure and by springs in and 49 upon an emergency reduction in brake pipe pressure. It will be further noted that the size of the service auxiliary slide valve 54 need only be large enough to control the one communication, that is, between ports 82 and 83, and its resistance to movement will not therefore materially aflect the differential of pressures required to deflect the diaphragm.

The bias or stabilizing spring 5i ensures that the piston 12 and emergency auxiliary slide valve 20 will not operate upon a service reduction in brake pipe pressure, but an emergency reduction in brake pipe pressure will ensure the differential required on this piston to move the auxiliary slide valve 26 to provide for sudden venting of fluid under pressure from the brake pipe il, while this sudden venting of fluid under pressure rom the brake pipe will ensure operation of the main slide valve it) by the piston ii. In this connection it should be noted that the emergency auxiliary slide valve 213 controls only one communicaticn as is the case with the service auxiliary slide valve it, and may therefore be relatively small as compared to the area of the'piston i2, so that any changes in the static resistance to movement of this valve will not materially affect the differential of pressures required on said piston to move said piston and valve.

Upon an emergency reduction in brake pipe pressure the diaphragm 29 deflects into engagement with the follower ring 33 and thereby moves the slide valve 5 to an overtravel position in which the service port 83 is lapped, as above explained. This prevents the venting of fluid under pressure from the valve chamber i5 and quick action chamber is through the service port 83 while obtaining the diflerential of pressures required on piston 52 to move said piston and the auxiliary valve 28 to the positionfor efiecting operation of the brake pipe ventvalve device. However, the provision of this overtravel position necessitates the use or spring 59 and the movable stop 38' and greater deflection of the diaphragm 29.

If desired, this overtravel position of the auxiliary slide valve 44 may be dispensed with along with the spring 49 and spring stop it, and the deflection of the flexible diaphragm could then be so limited that the service vent ports would be open while attaining the differential of pressures required on piston l2 to move said piston and the auxiliary slidevalve 23 to the position for eiiecting the operation of the brake pipe vent valve device upon an emergency reduction in brake pipe pressure. Such a modified construction is shown in Fig. 20f the drawings.

The fluid pressure brake equipment shown in Fig. 2 of the drawings comprises an emergency valve device the casing of which is substantially the same as that disclosed in Fig. -l of the drawings. An emergency piston 94 is mounted in the casing and has the chamber it at one side open to the brake pipe H and the chamber it at the opposite side open to the quick action chamber i8.

A flexible diaphragm $5 is secured to said piston by means of a clamping ring 96 having screwthreaded engagement with the piston. The ring 96 carries one end of a stern iii, while the other end of said stem extends through a central aper ture in the plunger 62 and is slidably mounted in a suitable bore in a cover 93 which is secured to the emergency valve device.

A main slide valve 99 is disposed in the valve chamber it between shoulders E59 and iii! on the piston stem 91. The emergency auxiliary slide valve 20 is mounted to slide on the main slide valve 99 and is disposed in a recess in the stern 9'! for movement therewith.

The stem 9? is provided With a shoulder Hi2 adapted to engage the plunger 52 for defining the normal position of the piston 23% and valves 28 and 99. A movable plunger ms is slidably mounted in the left hand end of the stem 9?. A spring lo l in the stem 97 acts on the plunger Hi3 urging same against a shoulder Hi5 formed in said stem, in which position the right hand face of the plunger engages the end of the main slide valve 99 while a certain clearance exists between the shoulder It! on said stem and the end of the main slide valve.

The main slide valve 99 is like that shown in Fig. 1 of the drawings except that the service port 83 is arranged to be controlled by a poppet valve Hi5 which is slidably mounted in a suitable bore in the right hand end. of said slide valve and which is adapted to be operated by the flexible diaphragm 95.

The diaphragm 95 has at one side a chamber [0! open through a central aperture its in the piston 94 to the brake pipe chamber l3, and has at the opposite side a chamber I89 open to the emergency valve chamber 16 through an aperture Hi3 provided through the clamping ring 96 below the stem 91.

A follower plate Hi is disposed in chamber I99 against the diaphragm 95 and is provided with a stud H2 which extends through a suitable opening in said diaphragm into chamber H37. A follower plate I I3 is disposed in chamber I01 against the diaphragm and has a central opening through which the stud H2 extends. A nut H is provided on the stud M2 to clamp the follower plates i H and H3 to the diaphragm 95 so as to move with said diaphragm upon deflection thereof.

The follower I i l is provided with an outstanding lug H5 which projects through the aperture Hll in the clamping ring 96. This lug is provided with a chamber 1 l6, and an opening 1 I7 in axial alignment with the service auxiliary valve I06 connects said chamber to the emergency valve chamber it.

The service auxiliary valve N35 is provided with a stem H8 which loosely extends through the opening H! in the lug H5 and which is provided within chamber MS with a head he of greater diameter than that of the opening H1. A spring 126 in chamber H6 acts on the head 3 l9 urging same in a direction towards the left hand into engagement with the portion of lug H5 surrounding the opening HT.

A leaf spring l2l is provided in chamber Hi! between the piston 94 and follower H3 and in this construction has the same function as the service spring 46 disclosed in Fig. 1 of the drawings. 1

In operation, the brake equipment is initially charged with fluid under pressure in the same manner as described in connection with the construction shown in Fig. 1 of the drawings.

When, upon a service reduction in brake pipe pressure, suflicient diiferentialof fluid'pressures is obtained on the diaphragm 95, said diaphragm deflects towards the right hand against the opposing pressure of spring E! i. This movement of the diaphragm pulls the service auxiliary valve 186 from its seat to permit venting of fluid under pressure from the valve chamber IS and quick action chamber i8 to the service port 33 and from thence to the atmosphere so as to prevent movement of the piston 95 and emergency auxiliary valve 28 upon a service reduction in brake pipe pressure in the. same manner as accomplished by the diaphragm 29 and service auxiliary valve it in the construction shown in Fig. -1 of the drawings. i

It will be noted that in the construction shown in Fig. 2 the action of spring ifi i through plunger 193 on the end of the main slide valve 99 stabilizes the emergency piston 9 against undesired movement to emergency position upon a service reduction in brake pipe pressure as is accomplished by spring 50 in the construction shown in Fig. 1 of the drawings. This stabilization is however dependent upon the static resistance to movement of the main slide valve 99 being sufiiciently greater than the pressure of spring I64 to ensure the proper operation, whereas in the construction previously describedthe stabilizing action of spring 50 is independent of the main slide valve l9.

It will be evident that upon an emergency reduction in brake pipe pressure the service auxiliary valve Hi8 will operate to permit venting of fluid under pressure from the emergency valve chamber i5 and quick action chamber l8 the same as upon a service reduction in brake pipe pressure, so that the differential of fluid pressures required to move the piston 94 against the pressure of stabilizing spring Hi4 must be obtained while this service venting is taking place in contrast to the construction shown in Fig. 1 in which the service auxiliary valve M has an overtravel position to prevent service venting of fluid under pressure from the valve chamber l8 and quick action chamber [8 upon an emergency reduction in brake pipe pressure.

While the stabilizing'spring Hi4 acts in the same capacity as the spring 53 in the construc tion shown in Fig. l to oppose operation of the emergency piston to move the emergency auxiliary valve 28 to the position for effecting operation of the brake pipe vent valve 65, it will be evident that movement of the main slide valve 99 to the position for supplying fluid under pressure to the brake cylinder 9 is not opposed by this spring in contrast to the action of spring 55 in the construction shown in Fig. 1.

The spring I20 is provided between the service valve Hi6 and diaphragm Hi to permit movement of said diaphragm towards the left hand relative to said valve so as to prevent the seating face of said valve being subjected to and thus possibly becoming damaged by the differential of pressures developed on the diaphragm upon an increase in brake pipe pressure and particularly where this increase is rapid and the differential developed is relatively high as may occur in back-dump operation of the device in eifecting a release of the brakes after an emergency application.

In the embodiments of the invention shown in Figs. 1 and 2, the flexible diaphragm controls the service auxiliary valve for venting fluid under pressure from the emergency valve chamber it and quick action chamber I 8 upon a service reduction in brake pipe pressure, while the supply of fluid under pressure to the vent valve device is controlled by an emergency auxiliary slide valve 20 which is operative by the emergency piston and therefore independent of the service auxiliary valve. While these constructions provide the smallest possible size of service auxiliary valve to be operated by a flexible diaphragm which in turn is limited in size to substantially the diameter of the emergency piston, it is however possible that the functions of both auxiliary valves may be combined in one auxiliary valve and be controlled by a flexible diaphragm associated with the emergency piston. Such a construction is disclosed in Fig. 3 of the drawings.

According to the construction shown in Fig. 3 of the drawings, an auxiliary slide valve 523 is provided on a main slide valve l 22 to be operated by the diaphragm controlled stem Al. The main slide valve I22 is the same as that shown in Fig.

1 of the drawings except that the upper end of the emergency port 85 is relocated so as to be controlled by the auxiliary slide valve I23 which for this purpose is slightly larger than the auxiliary slide valve 34 shown in Fig. 1 of the drawings. Since the only function of piston !2 in the construction shown in Fig. 3 is to operate the main slide valve 222 there is no lost motion provided between the spaced shoulders 22 and 23 on the piston stem 2i and the main slide valve 522 as was the case in the construction shown in Fig. 1 where the piston E2 was required to move the auxiliary slide valve 20 relative to the main slide valve l9.

In operation, when a service reduction in brake pipe pressure is effected the flexible diaphragm 29 responds and moves the auxiliary slide valve I23 to service position defined by the engagement of spring stop 18 with stop 35. In this position the service ports 82 and 83 register to permit venting of fluid under pressure from the emergency valve chamber l6 and quick action chamber 18, as occurs in the construction shown in Fig. 1, but also in this position the auxiliary slide valve l2l laps the emergency port 85. When an emergency reduction in brake pipe pressure is effected, the flexible diaphragm 29 deflects until the follower engages the ring 33 and thus moves the auxiliary slide valve I23 to the overtravel position in which the service port 83 is lapped, as in the construction shown in Fig. 1 of the drawings, but also in this overtravel position, the emergency port 36 is uncovered which permits fluid under pressure to flow from the valve chamber i5 and quick action chamber 18 to the vent valve piston chamber 16. The vent valve piston 1 3 is thereby operated to open the vent valve 55 to eflect sudden venting of fluid under pressure from the brake pipe I l and emergency piston chamber is whereupon the emergency piston l2 moves the main slide valve I22 to emergency position to supply fluid under pressure to the brake cylinder 9 as occurs in the construction shown in Fig. 1 of the drawings.

In effecting a release of the brakes after an application the equipment shown in Fig. 3 of the drawings operates in the same manner as that shown in Fig. 1.

It will be evident that since in the construction shown in Fig. 3 of the drawings, the emergency piston l2 does not have movement relative to the main slide valve I22, its travel is less in eflecting an emergency application of the brakes than is the case in the equipment shown in Figs. 1 and 2 of the drawings, and this is desirable for various reasons such as from the standpoint of wear of the piston.

Due to the fact that the auxiliary slide valve I23 may be somewhat larger than the valve 44 shown in Fig. l and may therefore have a slightly greater resistance to movement, the force of springs 35 and 49 on the diaphragm may be somewhat less than in the construction shown in Fig. 1 in order that the flexible diaphragm 29 shown in Fig. 3 will operate upon substantially the same differentials of fluid pressures as re quired to operate the diaphragm 29 in the construction shown in Fig. 1.

It will now be noted that in accordance with the invention, a flexible diaphragm of substantially the same area as the emergency piston is provided for effecting operation of a relatively .small valve to vent fluid under pressure from the quick action chamber upon a service reduction in brake pipe pressure, while according to the constructions shown in Figs. 1 and 2 of the drawings, a relatively small valve is provided to be actuated by the emergency piston upon an emergency reduction in brake pipe pressure to effect operation of the brake pipe vent valve. The functions of these two relatively small valves are contained in one auxiliary valve adapted to be minimum of change in said valves. It is desirable ithat this diaphragm will have as large an area as possible as restricted by the diameter of the emergency piston, and the construction shown inFigs. 1 '3 of the drawings discloses the manner in which the large area is obtained.

While several illustrative embodiments of the invention have been described in detail, it is not my intention to limit its scope to these embodiments or otherwise than by the terms of the appended claims.

Having now described my invention, what I claim as new and desire to secure by Letters'Patent, is:

1. In a fluid pressure brakein combination, a brake pipe, a valve operative to eflect an emergency operation, a piston subject to the opposing pressures of said brake pipe a quick action chamber and operative upon emergency reduction in brake pipe pressure to eiiect the operation of said valve, valve means operative to vent fluid under pressure from said chamber at .a service rate, and a flexible diaphragm carried by said piston also subject to the opposing pressures of said brake pipe and quick action chamber and operative upon a service reduction in brake pipe pressure to eflect the operation of said valve means.

2. In a fluid pressure brake, in combination, a brake pipe, a valve operative to effect an emergency operation, a piston subject to the opposing pressures of said brake pipe and a quick action chamber and operative upon a reduction in brake pipe pressure to efiect'the operation of said valve, 2. flexible diaphragm carried by said piston and also subject to the opposing pressures of said closed in the above mentioned patent with a brake pipe and chamber, valve means operative by said diaphragm upon a service rate of reduc tion in brake pipe pressure to reduce the pressure of fluid in said chamber at a corresponding rate, and means cooperative with the service rate of venting of fluid under pressure from said chamber to prevent the operation of said piston upon a reduction in brake pipe pressure at a rate less than an emergency rate.

3. In a fluid pressure brake, in combination, a brake pipe, a valve operative to effect an emergency operation, apiston subject to the opposing pressures of said brake pipe and a quick action chamber and operative upon an emergency reduction in brake pipe pressure to effect the operation of said valve, a flex ble diaphragm carried by said piston and also subject to the opposing means movable by saiddiaphragm to a service position upon a service rate of reduction in brake pipe pressure to vent fluid under pressure from said chamber at a corresponding rate, and means ior preventing said operation oi'said valve means upon a reduction in brake pipe pressure at a rate less than a service rate.

4. In a fluid pressure brake, in combination, a brake pipe; a valve operative to efiect an emergency operation, a piston subject to the opposing pressures of brake pipe and a quick action chamber and operative to effect the operation of said valve, a flexible diaphragm carried by said piston and also subject to the opposing pressures of said brake pipe and chamber, valve means operative by said diaphragm upon a reduction in brake pipe pressure tovent fluid under pressure from said chamber, and means for limiting the rate at which fluidunder pressure is vented from said chamber by the operation of said valve means to a degree whereby upon an emergency reduction in brake pipe pressure 'suiiicient differential of pressures will be obtained on said piston to effect the operation of said valve. 7

5. In a fluid pressure brake, in combination, a brake pipe, a valve operative to eiTect an emergency operation, a piston subject to the opposing pressures of said brake pipe and a quickaction chamber and operative upon an emergency reduction in brake pipe pressure to efiect the operation of said valve, valve means movable to a service position for venting fluid under pressure from said chamber at a service rate to prevent operation of said piston upon a service rate of reduction in brake pipe pressure, a flexible diaphragm carried by said piston and also subject to the opposing pressures of said brake pipe and chamber and operative upon a service reduction in brake pipe pressure to move said valve means to said service position, and means for preventing I operation of said diaphragm upon a reduction in brake pipe pressure at a rate less than a service rate.

6. In a fluid pressure brake, in combination, a brake pipe, a valve operative to efiect an emergency operation, a piston subject to the opposing pressures of said brake pipe and a quick action chamber and operative upon an emergency reduction in brake pipe pressure to efiect the operation of said valve, valve means movable to a service position for venting fluid under pressure from said chamber at a service rate to prevent operation of said piston upon a service rate of reduction in brake pipe pressure, and movable to another position for closing the venting communication which is opened in service position thereof, a flexible diaphragm carried by said piston and also subject to the opposing pressures of said brake pipe and chamber and operative upon a reduction in brake pipe pressure to move said valve to said positions, means for preventing operation oi said diaphragm upon a reduction in brake pipe pressure at a rate less than a service rate, and means for deflningthe service position of said valve means and for preventing operation of said diaphragm to move said valve means to the other position upon'a reduction in brake pipe pressure at a rate less than an emergency rate.

7. In a fluid pressure brake, in combination, a

brake pipe, a main slide valve movable to a position for effecting an application of the brakes, an auxiliary slide valve. carried by said main slide valve movable relative to said main slide valve in the normal position thereof to a position ior effecting sudden venting of fluid under pressure from said'brake pipe, a piston subject to the opposing pressures of said brake pipe and chamber and operative upon an emergency rate of reduction in brake pipe pressure to first move said auxiliary slide valve to they position for effecting venting of fluid under pressure from said brake pipe and then move said main slide valve to the position for effecting an application of the brakes, another auxiliary slide valve mounted on said main slide valve and movable relatively thereto to a service position for venting fluid under pressure from said quick action chamber at a service rate, a flem'ble diaphragm carried by said piston and also subject tothe opposing pressures of said brake pipe and quick action chamber and operative upon a service rate of reduction in brake pipe pressure to eiiect the movement of said other auxiliary slide valve to service position, and means for preventing operation of said diaphragm upon a reduction in brake pipe pressure at a rate less than a service rate.

8. In a fluid pressure brake, in combination, a brake pipe, a main slide valve movable to a position for effecting an application of they brakes, an auxiliary slide valve carried by said main slide valve and movable relative to said main slide valve in the normal position thereof to a position for effecting sudden venting of fluid valve mounted on said main slide valve and movable relatively thereto to a service position for venting fluid under pressure from said quick action chamber at a service rate, a flexible dia phragm carried by said piston and also subject to the opposing pressures of said brake pipe and quick action chamber and operative upon a service rate of reduction in brake pipe pressure to effect the movement of said other auxiliary slide valve to service position, means for preventing movement of said other auxiliary slide valve past service position by the operation of said diaphragm, and means for preventing operation of said diaphragm upon a reduction in brake pipe pressure at a rate less than a service rate.

9. In a fluid pressure brake, in combination, a brake pipe, a main slide valve movable to a position for effecting an application of the brakes, an auxiliary slide valve carried by said main slide valve and movable relative to said main slide valve in the normal position thereof to a position for efiecting sudden venting of fluid under presbrake pipe and then move said main slide valve to the position for effecting an application of the brakes, another auxiliary slide valve mounted on said main slide valve and movable relatively thereto to a service position for venting fluid under pressure from said quick action chamber ata'service rate, and movable further to another position for closing the venting communication to said chamber, a flexible diaphragm carried by said piston and also subject tolthe 0pposing pressures of said brake pipe and chamber and operative upon a service reduction in brake pipe pressure to move said other auxiliary slide valve to service position and upon an emergency reduction in brake pipe pressure to move said other auxiliary slide. valve to said other position, means for preventing operation of said diaphragm upon a reduction in brake pipe pressure at a rate less than a service rate, and means for defining the service position of said other auxiliary slide valve and also operative to prevent operation of said diaphragm to move said other auxiliary slide valve to its other position upon a reduction in brake pipe pressure at a rate less than an emergency rate.

10. In a fluid pressure brake, in combination, a brake pipe, a main slide valve movable to a position for effecting an application of the brakes, an auxiliary slide valve carried by said main slide valve and movable relative to said main slide valve in the normal position thereof to a position for effecting sudden venting of fluid under pressure from said brake pipe, a piston subject to the opposing pressures of said brake pipe and chamber and operative upon an emergency rate of reduction in brake pipe pressure to .first move said auxiliary slide valve to the position for effecting venting of fluid under pressure from said brake pipe and then move said main slide valve to the position for effecting an application of the brakes, another auxiliary slide valve mounted on said main slide valve and movable relatively thereto to a service position for venting fluid under pressure from said quick action chamber at a service rate, a movable abutment also subject to the opposing pressures of said brake pipe and chamber and operative upon a reduction in brake pipe pressure to move said other auxiliary slide valve to said service position, and means for preventing operation of said movable abutment upon a reduction in brake pipe pressure at a rate less than a service rate.

11. In a fluid pressure brake, in combination, a brake pipe, a main slide valve movable to a position for effecting an application of the brakes, a piston subject to the opposing pressures of said brake pipe and a quick action chamber and operative upon a sudden reduction in brake pipe pressure to move said slide valve to said position, an auxiliary slide valve carried by said main slide valve and movable relatively thereto to a service position for venting fluid under pressure from said quick action chamber at a service rate and movable further to another position for effecting sudden reduction in brake pipe pressure, a flexible diaphragm carried by said piston and also subject to the opposing pressures of said brake pipe and chamber and operative upon a service reduction in brake pipe pressure to move said auxiliary slide valve to said service position and upon an emergency reduction in brake pipe pressure to move said auxiliary slide valve to said other position, means for preventing operation of said diaphragm upon a reduction in brake pipe pressure at a rate less than a service rate, and means for preventing operation of said diaphragm to move said auxiliary valve to said other position upon a reduction in brake pipe pressure at a rate less than an emergency rate.

12. In a fluid pressure brake, in combination, a brake pipe, a valve operative to effect an emergency operation, a piston subject to the opposing pressures of said brake pipe and a quick action chamber and operative upon an emergency reduction in brake pipe pressure to effect the operation of said valve, valve means operative to reduce the pressure of fluid in said chamber at a service rate to prevent operation of said piston upon a service rate of reduction in brake pipe pressure, said piston including a flexible diaphragm of substantially the same diameter as said piston and also subject to the opposing pressures of said brake pipe and chamber and movable relatively to said piston upon a service reduction in brake pipe pressure to effect opera tion of said valve means.

13. In a fluid pressure brake, in combination, a brake pipe, a valve operative to effect an emergency operation, a piston subject to the opposing pressures of said brake pipe and a quick action chamber and operative upon an emergency reduction in brake pipe pressure to effect the operation of said valve, valve means operative to reduce the pressure of in said chamber at a service rate to prevent operation of said piston upon a service rate of reduction in brake pipe pressure, said piston including a flexible diaphragm of substantially the same diameter as said piston and also subject to the opposing pressures of said brake pipe and chamber and movable relatively to said piston upon a service reduction in brake pipe pressure to effect operation of said valve means, and a spring carried by said piston and acting on said diaphragm to prevent deflection thereof upon a reduction in brake pipe pressure at a rate less than a service rate.

1 In a fluid pressure brake, in combination, a brake pipe, a valve operative to effect an emer-- gency operation, a piston subject to the opposing pressures of said brake pipe and a quick action chamber and operative upon an emergency reduction in brake pipe pressure to effect the operation of said valve, valve means movable to a service position for reducing the pressure of fluid in said chamber at a service rate to prevent operation of said piston upon a service rate of reduction in brake pipe pressure, said valve means being movable through service position to another position, said piston including a flexible diaphragm of substantially the same diameter as said piston and also subject to the opposing pressures of said brake pipe and chamber and operative according to the rate of reduction in brake pipe pressure to move said valve means to either service position or said other position, a spring carried by said piston and acting on said diaphragm at all'times to prevent operation thereof upon a reduction in brake pipe pressure at a rate less than a service rate, and another spring adapted to act on said diaphragm upon movement of said valve means to service position for defining said service position and for preventing operation of said diaphragm to move said valve means to said other position upon a reduction in brake pipe pressure at a rate less than an emergency rate.

15. In a fluid pressure brake, in combination, a brake pipe, a valve operative to effect an emergency operation, a piston subject to the pposing pressures of said brake pipe and a quick action chamber and operative upon an emer-,

gency reduction in brake pipe pressure to effect the operation of said valve, valve means operative to reduce the'pressurein said chamber at a service rate to prevent operation of said piston upon a reduction in brake pipe pressure at a rate less than an emergency rate, said piston having an axial bore slightly smaller in diameter than said piston and open at one end, a flexible diaphragm having an outer cylindrical portion engaging the side wall of said bore and having at one end of said cylindrical portion an inwardly directed annulan, clamping flange, means clamping said flange to said piston, said diaphragm having a central annular clamping flange and an annular convolution'joining the other end of said cylindrical portion to the outer edge of said central clamping flange, said piston having means for subjecting one face of said diaphragm to brake pipe pressure and the opposite face to the pressure of fluid in said chamber, and means secured to said central clamping flange and operatively connected to said valve means whereby deflection of said diaphragm upon a service rate of reduction in brake pipe pressure is operative to efiect operation of said valve means.

16. In a fluid pressure brake, in combination, a brake pipe, a valve operative to eiiect an emergency operation, a piston subject to the opposing pressures of said brake pipe and a quick action chamber and operative upon an emergency reduction in brake pipe pressure to effect the oper ation of said valve, valve means operative to reduce the pressure in said chamber at a service .rate to prevent operation of said piston upon a reduction in brake pipe pressure at a rate less than an emergency rate, said piston having an axial bore slightly smaller in diameter than said piston and open at one end, a flexible diaphragm having an outer cylindrical portion engaging the side wall of said bore and having at one end of said cylindrical portion an inwardly directed annular clamping flange, means clamping said flange to said piston, said diaphragm having a central annular clamping flange and an annular convolution joining the other end of said cylindrical portion to the outer edge of said central clamping flange, said piston having means for subjecting one face of said diaphragm to brake pipe pressure and the opposite face to the pressure of fluid in said chamber, means secured to said central clamping flange and operatively connected to said valve means for operating said valve means upon deflection of said diaphragm, a spring associated with said piston and acting on said diaphragm for preventing deflection thereof upon a reduction in brake pipe pressure at a rate less than a service rate, and another spring operative to define the position of said diaphragm and valve means in which the pressure of fluid in said chamber is reduced, said other spring being also adapted to prevent operation of said diaphragm to move said valve means past said position upon a reduction in brake pipe pressure at a rate less than an emergency rate.

17. In a fluid pressure brake, in combination, a brake pipe, a main slide valve operative to effect an application of the brakes, an auxiliary slide valve mounted on and movable relative to said main slide valve to effect a sudden venting of fluid under pressure from said brake pipe, a piston subject to the opposing pressures of said brake pipe and a quick action chamber, said piston having a stem connected to said main and auxiliary slide valves and operative uponan emergency reduction in brake pipe pressure to effect the operation first of said auxiliary slide valve and then of said main slide valve, another auxiliary slide valve mounted on and movable relative to said main slide valve to a service position for efiecting a service rate of reduction in pressure in said chamber to prevent operation of said piston upon a service rate of reduction in brake pipe pressure, said piston including a flexible diaphragm'also subject to the opposing pressures of said brake pipe and chamber, means supported at one end in said piston stem and connected at the other end to said diaphragm and operatively connected to said other auxiliary slide valve, said diaphragm being operative upon a service rate of reduction in brake pipe pressure to operate said means to move said other auxiliary slide valve to said service position, and means for preventing operation of said diaphragm upon a reduction in brake pipe pressure at a rate less than a service rate.

18. In a fluid pressure brake, in combination, a brake pipe, a valve operative to effect an emergency operation, a piston subject to the opposing pressures of said brake pipe and a quick action chamber and operative upon an emergency reduction in brake pipe pressure to effect the operation of said valve, valve means operative to vent fluid under pressure from said chamber at a service rate, a flexible diaphragm carried by said piston and also subject to the opposing pressures of said brake pipe and chamber and operative upon a service reduction in brake pipe pressure to effect the operation of said valve means, a yielding resistance means for preventing movement of said diaphragm to operate said valve means to vent fluid under pressure from the quick action chamber at a rate less than a service rate of reduction in brake pipe pressure, and a yielding resistance means for preventing movement of said emergency piston unless the brake pipe pressure is reduced at an emergency rate.

19. In a fluid pressure brake, in combination, a brake pipe, a valve operative to effect an emergency operation, a piston subject to the opposing pressures of said brake pipe and a quick action chamber and operative upon an emergency reduction in brake pipe pressure to effect the opera tion of said valve, valve means movable to a Service position for establishing a communication for venting fluid under pressure from said chamber at a service rate and movable further to another position for closing said communication, a flexible diaphragm associated with said piston and also subject to the opposing pressures of said brake pipe and chamber and operative upon a service reduction in brake pipe pressure to move said valve means to said positions, yielding resistance means for preventing movement of said diaphragm to operate said valve means upon a reduction in brake pipe pressure at a rate less than a service rate, yielding resistance means for defining said'service position and for preventing operation of said diaphragm to move said valve means to said other position upon a reduction in brake pipe pressure at a rate less than an emergency rate, and yielding resistance means for preventing movement'of said piston upon a reduction in brake pipe pressure at a rate less than an emergency rate.

CLYDE C. FARMER. 

